Phased array antenna system including a modular control and monitoring architecture

What is claimed is: 1. A phased array antenna system ( 100 ), comprising: a plurality of radio frequency (RF) tile sub-arrays ( 104 ) arranged in a certain pattern to define an RF aperture ( 106 ), each RF tile sub-array ( 104 ) comprising a multiplicity of RF elements ( 112 ), a multiplicity of RF integrated circuits ( 118 ) operatively connected to one or more of the multiplicity of RF elements ( 112 ), a configuration storage device ( 422 ) configured to store data comprising calibration and configuration information that is unique to the RF tile sub-array, at least one true time delay circuit ( 416 ) per RF beam tracked or steered by the RF tile subarray, and a tile control integrated circuit ( 120 ) operatively connected to each of the multiplicity of RF integrated circuits ( 118 ), wherein the tile control integrated circuit ( 120 ), the multiplicity of RF integrated circuits ( 118 ), the multiplicity of RF elements, the at least one true time delay circuit, and the configuration storage device ( 422 ) are disposed on a single associated RF tile sub-array, each RF element ( 112 ) is separately controllable for steering or tracking an RF beam ( 114 , 116 ) that is generated or received by the RF element ( 112 ); and an antenna controller ( 124 ) configured to process data for steering or tracking one or more RF beams by the multiplicity of RF elements, wherein the antenna controller comprises: an antenna manager ( 126 ), the antenna manager being configured to receive data for steering or tracking the one or more RF beams ( 114 , 116 ); and a plurality of aperture state machines ( 128 a , 128 b ), an aperture state machine being associated with each RF tile sub-array for controlling operation of the associated RF tile sub-array, wherein an RF tile bus operatively couples each aperture state machine ( 128 a , 128 b ) to the associated RF tile sub-array ( 104 ), wherein each aperture state machine ( 128 , 200 ) comprises: an RF element compensation table ( 210 ) that receives information from the antenna manager ( 126 ) for use in determining a steering or tracking solution and determines RF element phase compensation data based on the information; a tile multi-beam phase and true time delay calculator pipeline ( 212 ) that receives the RF element phase compensation data from the RF element compensation table and beam pointing information from the antenna manager, wherein the tile multi-beam phase and true time delay calculator pipeline determines a delay for each RF element of the associated RF sub-array based on the RF element phase compensation data and the beam pointing information; and a tile physical layer (PHY) interface ( 216 ) coupling the tile multi-beam phase and true time delay calculator pipeline to an associated RF tile bus; and wherein the antenna manager is configured to transmit control and status data and the beam pointing information to one of the aperture state machines ( 128 a , 128 b ) in response to RF elements ( 112 ) of the RF tile sub-array ( 104 ) associated with the one aperture state machine ( 128 a , 128 b ) being selected for use for steering or tracking the one or more RF beams ( 114 , 116 ). 2. The phased array antenna system ( 100 ) of claim 1 , wherein each aperture state machine ( 128 , 200 ) is configured for processing RF element phase data for the associated RF tile sub-array using the beam pointing information ( 214 ) and RF element phase compensation data ( 602 ), the RF element phase data allows the associated RF tile sub-array to steer or track the one or more RF beams, the plurality of aperture state machines provides concurrent processing of RF tile sub-array phase data from a steering or tracking solution to loading the RF element phase data in the associated RF tile sub-arrays. 3. The phased array antenna system ( 100 ) of claim 1 , wherein each aperture state machine ( 128 , 200 ) further comprises: a tile command and direct write module ( 218 ) for receiving tile command and write information in a tile write DMA space ( 204 ) from the antenna manager ( 126 ), the tile command and direct write module being connected to the tile PHY interface ( 216 ) for sending the tile command and write information to the associated RF tile sub-array ( 104 ) via the associated RF tile bus ( 130 ); and a tile status and read-back module ( 220 ) for receiving status and read-back information from the associated RF tile sub-array ( 104 ) via an associated RF tile bus ( 130 ), the tile status and read-back module ( 220 ) being connected to the tile PHY interface ( 216 ). 4. The phased array antenna system ( 100 ) of claim 1 , wherein the aperture state machine ( 128 , 200 ) and an associated RF tile bus provide a direct memory access from an antenna manager of the antenna controller to the associated RF tile sub-array. 5. The phased array antenna system ( 100 ) of claim 1 , wherein each RF tile sub-array ( 104 ) comprises a tile connector ( 300 ), the tile connector comprising: a tile bus connection ( 302 ) including a tile data input/output port ( 304 ) and a tile clock input port ( 306 ); an RF signal port ( 312 ) for receiving and transmitting RF signals from and to the RF tile sub-array; and an RF tile power and returns port ( 316 ) for providing electrical power to the RF tile sub-array, wherein the tile connector for each RF tile sub-array of the plurality of RF tile sub-arrays is located at a different location on each RF tile sub-array or a perimeter of each RF tile sub-array to provide optimal connectivity and routing of RF signal wiring and wherein the tile connector comprises an integrated interface device comprising the tile data input/output port, the tile clock input port, the RF signal port and the RF tile power and returns port in a single connector configured to disconnect the RF tile sub-array for replacement of the tile subarray. 6. The phased array antenna system ( 100 ) of claim 5 , wherein each RF tile sub-array ( 104 ) further comprises: a tile data input/output link ( 308 ) that connects the tile control integrated circuit to an associated RF tile bus ( 130 ) via the tile connector ( 300 ); and a tile clock link ( 310 ) that connects the tile control integrated circuit ( 120 ) to the RF tile bus ( 130 ) via the tile connector ( 300 ), wherein the tile control integrated circuit ( 120 ) is configured to individually control the multiplicity of RF elements ( 112 ) in response to data received from the antenna controller ( 124 ) over the RF tile bus ( 130 ). 7. The phased array antenna system ( 100 ) of claim 6 , wherein each RF integrated circuit ( 118 ) is operatively connected to one, two or four RF elements ( 112 ) for controlling operation of an operatively connected RF element or RF elements ( 112 ). 8. The phased array antenna system ( 100 ) of claim 7 , wherein each RF tile sub-array ( 104 ) comprises a predetermined shape and the multiplicity of RF integrated circuits ( 118 ) are arranged in quadrants ( 412 ) on the RF tile sub-array ( 104 ) and each quadrant of RF integrated circuits are operatively connected to the tile control integrated circuit by a clock and data serial bus matrix ( 414 ) that limits a number of interconnect pins on each RF integrated circuit to four. 9. The phased array antenna system ( 100 ) of claim 1 , wherein the RF integrated circuits ( 118 ) and the true time delay circuit ( 416 ) are connected as party line slaves with the tile control integrated circuit as master. 10. The phased array antenna system ( 100 ) of claim 1 , wherein the multiplicity of RF elements ( 112 ) of a particular RF tile sub-array ( 104 ) are calibrated in phase with one another to support a correlated beam function and the cal